// Macro for running Cbm with Geant3 or Geant4 (M. Al-Turany , D. Bertini) // Modified 22/06/2005 D.Bertini { TStopwatch timer; timer.Start(); gDebug=0; // Load basic libraries gROOT->LoadMacro("$VMCWORKDIR/gconfig/basiclibs.C"); basiclibs(); // Load this example libraries gSystem->Load("libGeoBase"); gSystem->Load("libParBase"); gSystem->Load("libBase"); gSystem->Load("libMCStack"); gSystem->Load("libField"); gSystem->Load("libPassive"); gSystem->Load("libMvd"); gSystem->Load("libEmc"); gSystem->Load("libDrcProp"); gSystem->Load("libDrc"); gSystem->Load("libGen"); gSystem->Load("libgenfit"); gSystem->Load("libtpc"); gSystem->Load("librecotasks"); gSystem->Load("libPGen"); CbmRunSim *fRun = new CbmRunSim(); // set the MC version used // ------------------------ fRun->SetName("TGeant4"); // Choose the Geant Navigation System // fRun->SetGeoModel("G3Native"); fRun->SetOutputFile("demoMC.root"); // Set Material file Name //----------------------- fRun->SetMaterials("media_pnd.geo"); std::cout<< "Materials set" << std::endl; // Create and add detectors //------------------------- CbmModule *Cave= new CbmCave("CAVE"); Cave->SetGeometryFileName("pndcave.geo"); fRun->AddModule(Cave); CbmModule *Pipe= new CbmPipe("PIPE"); Pipe->SetGeometryFileName("pipe.geo"); fRun->AddModule(Pipe); CbmModule *Magnet= new CbmMagnet("MAGNET"); Magnet->SetGeometryFileName("magnet.geo"); fRun->AddModule(Magnet); CbmDetector *Tpc = new TpcDetector("TPC", kTRUE); Tpc->SetGeometryFileName("tpc.geo"); fRun->AddModule(Tpc); //CbmDetector *Sts= new CbmTst("TST", kTRUE); //Sts->SetGeometryFileName("tst_mvd.geo"); //fRun->AddModule(Sts); CbmDetector *Mvd = new MvdMCDetector("MVD", kTRUE); Mvd->SetGeometryFileName("MVD_Rev14b_Corr+Dead.geo"); fRun->AddModule(Mvd); CbmDetector *Emc = new CbmEmc("EMC",kTRUE); Emc->SetGeometryFileName("emc_module1234.dat"); fRun->AddModule(Emc); // CbmDetector *Drc = new CbmDrc("DIRC", kTRUE); // Drc->SetGeometryFileName("dirc.geo"); // fRun->AddModule(Drc); //CbmModule *Target= new CbmTarget("Target"); //Target->SetGeometryFileName("target_vacuum.geo"); //fRun->AddModule(Target); //CbmDetector *Tof= new CbmTof("TOF", kTRUE ); //Tof->SetGeometryFileName("tof.geo"); //fRun->AddModule(Tof); //CbmDetector *Trd= new CbmTrd("TRD",kTRUE ); //Trd->SetGeometryFileName("trd_9.geo"); //fRun->AddModule(Trd); // CbmDetector *Rich= new CbmRich("RICH", kTRUE); // Rich->SetGeometryFileName("rich.geo"); // fRun->AddModule(Rich); //CbmDetector *Ecal= new CbmEcal("ECAL", kTRUE); //Ecal->SetGeometryFileName("ecal.geo"); //fRun->AddModule(Ecal); // Create and Set Event Generator //------------------------------- CbmPrimaryGenerator* primGen = new CbmPrimaryGenerator(); fRun->SetGenerator(primGen); // Urqmd Generator // CbmUrqmdGenerator* urqmdGen = new CbmUrqmdGenerator("../../input/00-03fm.100ev.f14"); // primGen->AddGenerator(urqmdGen); // Particle Generator //CbmParticleGenerator* partGen = new CbmParticleGenerator(211, 10, 1, 0,3,kTRUE); //primGen->AddGenerator(partGen); // Ion Generator // CbmIonGenerator *fIongen= new CbmIonGenerator(79, 197,79,1, 0.,0., 25, 0.,0.,-1.); // primGen->AddGenerator(fIongen); // Box Generator CbmBoxGenerator* boxGen = new CbmBoxGenerator(13, 1); // 13 = muon; 1 = multipl. boxGen->SetPRange(0.5,0.5); // GeV/c //setPRange vs setPtRange boxGen->SetPhiRange(0, 360); // Azimuth angle range [degree] boxGen->SetThetaRange(40, 60); // Polar angle in lab system range [degree] boxGen->SetXYZ(0., 0.37, 0.); // mm o cm ?? primGen->AddGenerator(boxGen); //CbmPrimaryGenerator* primGen = new CbmPrimaryGenerator(); fRun->SetGenerator(primGen); // PndDpmGenerator* dpmGen = new PndDpmGenerator("pgenerators/DpmEvtGen/Background-micro.root"); //primGen->AddGenerator(dpmGen); // Field Map Definition // -------------------- // 1- Reading the new field map in the old format // CbmFieldMap *fMagField= new CbmFieldMap("FIELD.v04_pavel.map"); // Constant Field PndConstField *fMagField=new PndConstField(); fMagField->SetField(0, 0 ,20. ); // values are in kG // MinX=-75, MinY=-40,MinZ=-12 ,MaxX=75, MaxY=40 ,MaxZ=124 ); // values are in cm fMagField->SetFieldRegion(-500, 500,-500, 500, -200, 200); // 2- Reading the new field map in the new format // CbmField *fMagField= new CbmFieldMapSym3("FieldActive"); // Active Shielding fRun->SetField(fMagField); fRun->SetStoreTraj(kTRUE); //fRun->SetStoreTraj(kFALSE); fRun->Init(); // -Trajectories Visualization (TGeoManager Only ) // ----------------------------------------------- ; // Set cuts for storing the trajectpries // CbmTrajFilter* trajFilter = CbmTrajFilter::Instance(); // trajFilter->SetStepSizeCut(0.01); // 1 cm // trajFilter->SetVertexCut(-2000., -2000., 4., 2000., 2000., 100.); // trajFilter->SetMomentumCutP(10e-3); // p_lab > 10 MeV // trajFilter->SetEnergyCut(0., 1.02); // 0 < Etot < 1.04 GeV // trajFilter->SetStorePrimaries(kTRUE); // trajFilter->SetStoreSecondaries(kTRUE); // Fill the Parameter containers for this run //------------------------------------------- CbmRuntimeDb *rtdb=fRun->GetRuntimeDb(); Bool_t kParameterMerged=kTRUE; CbmParRootFileIo* output=new CbmParRootFileIo(kParameterMerged); output->open("demoparams.root"); rtdb->setOutput(output); rtdb->saveOutput(); rtdb->print(); // Transport nEvents // ----------------- Int_t nEvents = 100; fRun->Run(nEvents); timer.Stop(); Double_t rtime = timer.RealTime(); Double_t ctime = timer.CpuTime(); printf("RealTime=%f seconds, CpuTime=%f seconds\n",rtime,ctime); }